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use crate::io::driver::{Handle, Interest, Registration}; use mio::event::Source; use std::fmt; use std::io; use std::ops::Deref; cfg_io_driver! { /// Associates an I/O resource that implements the [`std::io::Read`] and/or /// [`std::io::Write`] traits with the reactor that drives it. /// /// `PollEvented` uses [`Registration`] internally to take a type that /// implements [`mio::Evented`] as well as [`std::io::Read`] and or /// [`std::io::Write`] and associate it with a reactor that will drive it. /// /// Once the [`mio::Evented`] type is wrapped by `PollEvented`, it can be /// used from within the future's execution model. As such, the /// `PollEvented` type provides [`AsyncRead`] and [`AsyncWrite`] /// implementations using the underlying I/O resource as well as readiness /// events provided by the reactor. /// /// **Note**: While `PollEvented` is `Sync` (if the underlying I/O type is /// `Sync`), the caller must ensure that there are at most two tasks that /// use a `PollEvented` instance concurrently. One for reading and one for /// writing. While violating this requirement is "safe" from a Rust memory /// model point of view, it will result in unexpected behavior in the form /// of lost notifications and tasks hanging. /// /// ## Readiness events /// /// Besides just providing [`AsyncRead`] and [`AsyncWrite`] implementations, /// this type also supports access to the underlying readiness event stream. /// While similar in function to what [`Registration`] provides, the /// semantics are a bit different. /// /// Two functions are provided to access the readiness events: /// [`poll_read_ready`] and [`poll_write_ready`]. These functions return the /// current readiness state of the `PollEvented` instance. If /// [`poll_read_ready`] indicates read readiness, immediately calling /// [`poll_read_ready`] again will also indicate read readiness. /// /// When the operation is attempted and is unable to succeed due to the I/O /// resource not being ready, the caller must call [`clear_read_ready`] or /// [`clear_write_ready`]. This clears the readiness state until a new /// readiness event is received. /// /// This allows the caller to implement additional functions. For example, /// [`TcpListener`] implements poll_accept by using [`poll_read_ready`] and /// [`clear_read_ready`]. /// /// ## Platform-specific events /// /// `PollEvented` also allows receiving platform-specific `mio::Ready` events. /// These events are included as part of the read readiness event stream. The /// write readiness event stream is only for `Ready::writable()` events. /// /// [`std::io::Read`]: trait@std::io::Read /// [`std::io::Write`]: trait@std::io::Write /// [`AsyncRead`]: trait@AsyncRead /// [`AsyncWrite`]: trait@AsyncWrite /// [`mio::Evented`]: trait@mio::Evented /// [`Registration`]: struct@Registration /// [`TcpListener`]: struct@crate::net::TcpListener /// [`clear_read_ready`]: method@Self::clear_read_ready /// [`clear_write_ready`]: method@Self::clear_write_ready /// [`poll_read_ready`]: method@Self::poll_read_ready /// [`poll_write_ready`]: method@Self::poll_write_ready pub(crate) struct PollEvented<E: Source> { io: Option<E>, registration: Registration, } } // ===== impl PollEvented ===== impl<E: Source> PollEvented<E> { /// Creates a new `PollEvented` associated with the default reactor. /// /// # Panics /// /// This function panics if thread-local runtime is not set. /// /// The runtime is usually set implicitly when this function is called /// from a future driven by a tokio runtime, otherwise runtime can be set /// explicitly with [`Runtime::enter`](crate::runtime::Runtime::enter) function. #[cfg_attr(feature = "signal", allow(unused))] pub(crate) fn new(io: E) -> io::Result<Self> { PollEvented::new_with_interest(io, Interest::READABLE | Interest::WRITABLE) } /// Creates a new `PollEvented` associated with the default reactor, for /// specific `Interest` state. `new_with_interest` should be used over `new` /// when you need control over the readiness state, such as when a file /// descriptor only allows reads. This does not add `hup` or `error` so if /// you are interested in those states, you will need to add them to the /// readiness state passed to this function. /// /// # Panics /// /// This function panics if thread-local runtime is not set. /// /// The runtime is usually set implicitly when this function is called from /// a future driven by a tokio runtime, otherwise runtime can be set /// explicitly with [`Runtime::enter`](crate::runtime::Runtime::enter) /// function. #[cfg_attr(feature = "signal", allow(unused))] pub(crate) fn new_with_interest(io: E, interest: Interest) -> io::Result<Self> { Self::new_with_interest_and_handle(io, interest, Handle::current()) } pub(crate) fn new_with_interest_and_handle( mut io: E, interest: Interest, handle: Handle, ) -> io::Result<Self> { let registration = Registration::new_with_interest_and_handle(&mut io, interest, handle)?; Ok(Self { io: Some(io), registration, }) } /// Returns a reference to the registration pub(crate) fn registration(&self) -> &Registration { &self.registration } /// Deregister the inner io from the registration and returns a Result containing the inner io #[cfg(feature = "net")] pub(crate) fn into_inner(mut self) -> io::Result<E> { let mut inner = self.io.take().unwrap(); // As io shouldn't ever be None, just unwrap here. self.registration.deregister(&mut inner)?; Ok(inner) } } feature! { #![any(feature = "net", feature = "process")] use crate::io::ReadBuf; use std::task::{Context, Poll}; impl<E: Source> PollEvented<E> { // Safety: The caller must ensure that `E` can read into uninitialized memory pub(crate) unsafe fn poll_read<'a>( &'a self, cx: &mut Context<'_>, buf: &mut ReadBuf<'_>, ) -> Poll<io::Result<()>> where &'a E: io::Read + 'a, { use std::io::Read; let n = ready!(self.registration.poll_read_io(cx, || { let b = &mut *(buf.unfilled_mut() as *mut [std::mem::MaybeUninit<u8>] as *mut [u8]); self.io.as_ref().unwrap().read(b) }))?; // Safety: We trust `TcpStream::read` to have filled up `n` bytes in the // buffer. buf.assume_init(n); buf.advance(n); Poll::Ready(Ok(())) } pub(crate) fn poll_write<'a>(&'a self, cx: &mut Context<'_>, buf: &[u8]) -> Poll<io::Result<usize>> where &'a E: io::Write + 'a, { use std::io::Write; self.registration.poll_write_io(cx, || self.io.as_ref().unwrap().write(buf)) } #[cfg(feature = "net")] pub(crate) fn poll_write_vectored<'a>( &'a self, cx: &mut Context<'_>, bufs: &[io::IoSlice<'_>], ) -> Poll<io::Result<usize>> where &'a E: io::Write + 'a, { use std::io::Write; self.registration.poll_write_io(cx, || self.io.as_ref().unwrap().write_vectored(bufs)) } } } impl<E: Source> Deref for PollEvented<E> { type Target = E; fn deref(&self) -> &E { self.io.as_ref().unwrap() } } impl<E: Source + fmt::Debug> fmt::Debug for PollEvented<E> { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { f.debug_struct("PollEvented").field("io", &self.io).finish() } } impl<E: Source> Drop for PollEvented<E> { fn drop(&mut self) { if let Some(mut io) = self.io.take() { // Ignore errors let _ = self.registration.deregister(&mut io); } } }